An expression in the form of E = − ( constant ) ( 1 /n 2 ) is to be written. Concept introduction: Bohr’s atomic model had the following postulates: 1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus. 2) The energy of an electron changes sharply upon transition from one energy level to another. 3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/ 2 π . The equation to find the energy of a level in hydrogen-like atoms is, Δ E = − 2.18 × 10 − 18 J ( 1 n 2 )

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Answer 1

Question

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

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Answer 2

Question

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Expert Solution & Answer

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See solution

Answer 3

Question

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Expert Solution & Answer

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Check out a sample textbook solution

See solution

Answer 4

Question

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Answer 5

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Answer 6

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

Answer 7

Chapter 7, Problem 7.62P

(a)

Interpretation Introduction

Interpretation:

An expression in the form of E=−(constant)(1/n2) is to be written.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the energy of a level in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1n2)

Answer 8

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

Answer 9

(b)

Interpretation Introduction

Interpretation:

The ΔE between n=2 and n=3 is to be determined.

Concept introduction:

Bohr’s atomic model had the following postulates:

1) The electrons in atoms revolve around the nucleus in certain circular orbits. The orbits are the energy levels. The orbits closer to the nucleus are of lesser energy than the ones further from the nucleus.

2) The energy of an electron changes sharply upon transition from one energy level to another.

3) The angular momentum of an electron moving around the nucleus is quantized. Thus the angular momentum of an electron is a whole number multiple of h/2π.

The equation to find the difference in the energy between the two levels in hydrogen-like atoms is,

ΔE=−2.18×10−18 J(1nfinal2−1ninitial2) (2)

Here,

ΔE is the difference in the energy between two levels.

nfinal is the lower energy level.

ninitial is the higher energy level.

Answer 10

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Answer 11

(c)

Interpretation Introduction

Interpretation:

The wavelength of the photon that corresponds to ΔE=3.027×10-19 J is to be determined.

Concept introduction:

The difference between the energies of two energy levels is the amount of energy in a photon emitted or absorbed when an electron makes a transition. The energy of a photon emitted or absorbed by an electron is,

ΔE=hν

Here,

ΔE is the energy.

h is the Plank’s constant.

ν is the frequency

The equation to relate the frequency and wavelength of radiation is as follows:

ν=cλ

The above relation can be modified as follows:

ΔE=hcλ (3)

Answer 12

Expert Solution & Answer

Answer 13

Expert Solution & Answer

Answer 14

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Answer 15

Ch. 7.1 - Some diamonds appear yellow because they contain...Ch. 7.1 - Prob. 7.1BFP Ch. 7.1 - Prob. 7.2AFP Ch. 7.1 - Prob. 7.2BFP Ch. 7.2 - Prob. 7.3AFP Ch. 7.2 - Prob. 7.3BFP Ch. 7.2 - Prob. B7.1P Ch. 7.2 - Prob. B7.2P Ch. 7.3 - Prob. 7.4AFP Ch. 7.3 - Prob. 7.4BFP

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